DE102017207056A1 - Electric machine - Google Patents

Abstract

Electric machine comprising a stator magnetically acting with the stator rotor, wherein the rotor is rotatably mounted about an axis of rotation, a shaft (1, 11) on which the rotor is mounted, wherein the shaft (1, 11) is designed as a hollow shaft wherein the shaft has a section which is formed as an extruded profile (2, 12) and wherein the shaft (1, 11) has a first shaft end (3, 13) and a second shaft end (4, 14), wherein the first shaft end ( 3, 13) and the second shaft end (4, 14) with the extruded profile (2, 12) at the respective opposite ends of the extruded profile (2, 12) are permanently connected.

Description

Field of the invention

The present invention relates to an electric machine comprising a stator magnetically acting with the stator rotor, wherein the rotor is rotatably mounted about a rotation axis, a shaft on which the rotor is mounted, wherein the shaft is formed as a hollow shaft.

State of the art

Electrical machines heat up from electrical to mechanical energy during energy conversion and vice versa. To increase the efficiency of such electrical machines, it is therefore necessary to cool them. It is known to form shafts such electrical machines as hollow shafts, through which a cooling medium can flow. Other solutions provide a system in which the shaft bores and machined grooves, which are enclosed by a steel sleeve and thus form cooling channels.

The DE102012203697A1 shows an electric machine comprising a stator, a rotatably mounted about a rotation axis rotor, a shaft on which the rotor is mounted, wherein the shaft has an axial bore, an inflow member which extends into the axial bore, that is a cooling medium the inflow element can flow into the axial bore.

Summary of the invention

It is an object of the invention to improve electrical machines in the sense that a shaft is provided, which ensures an improved cooling of the electric machine and thereby space-saving, weight-reducing and inexpensive to produce.

The object is achieved by an electric machine having the features of claim 1.

According to the invention, an electric machine is provided, comprising a stator magnetically acting with the stator rotor, wherein the rotor is rotatably mounted about a rotation axis, a shaft on which the rotor is mounted, wherein the shaft is formed as a hollow shaft, wherein the shaft has a portion which is formed as an extruded profile and wherein the shaft has a first shaft end and a second shaft end, wherein the first shaft end and the second shaft end are permanently connected to the extruded profile at the respective opposite ends of the extruded profile.

A significant advantage of the inventive design of the shaft is that through the shaft, for example, another with this concentrically arranged shaft, without requiring additional space to run.

Further developments of the invention are specified in the dependent claims, the description and the accompanying drawings.

Preferably, the extruded profile is made of aluminum or aluminum alloy.

Aluminum or suitable aluminum alloys are preferably used in automotive and mechanical engineering because of their properties and because of weight reduction for such applications.

According to a further embodiment of the invention, the extruded profile has at least one channel through which a cooling medium can flow.

By extrusion, suitable geometries can be produced easily and inexpensively. As a result, cooling channels can be formed particularly cost-effectively and compactly in the shaft, at least in a desired section. The component can also be manufactured weight optimized.

According to one embodiment of the invention, the first shaft end and the second shaft end are made of steel.

The shaft ends or stub shafts are made more demanding and are therefore made of a different material than the section with the extruded profile.

In the region of the first shaft end and / or the second shaft end, the bearing of the shaft preferably takes place in a housing of the electrical machine.

The first shaft end and the second shaft end are connected according to a further embodiment of the invention by means of welding, in particular by means of friction welding, with the extruded profile.

Connecting different materials can often be a problem. Friction welding, in particular friction stir welding, has proven to be advantageous for joining steel and aluminum parts.

However, other known in the art connection methods, such as gluing, can be applied.

According to one embodiment of the invention, the first shaft end and / or the second shaft end and / or a first cylindrical body and / or a second cylindrical body have a configuration which causes a deflection of the cooling medium.

This embodiment is preferably formed on the extruded profile facing end side of the first shaft end and / or the second shaft end.

According to a further embodiment of the invention, a first cylindrical body is arranged in the first shaft end or in the extruded profile.

According to one embodiment of the invention, a second cylindrical body is arranged in the second shaft end or in the extruded profile.

The cylindrical bodies serve to ensure the coolant flow inlet and outlet or to separate the inlet and the outlet.

The first and second cylindrical bodies are preferably formed as sleeves, wherein the sleeves are arranged so that they form at least one channel, wherein a first channel defines the inlet and wherein a second channel defines the drain and the sleeves the inlet and outlet of Disconnect each other.

In a preferred embodiment, the first cylindrical body is pressed into the first shaft end or the extruded profile.

In a further preferred embodiment, the second cylindrical body is pressed into the second shaft end or the extruded profile.

The first and second cylindrical bodies are preferably made of steel, but may be made of any other suitable material.

list of figures

• 1 ist eine Schnittansicht einer Welle für eine elektrische Maschine in ersten erfindungsgemäßen Ausführungsform.
• 2 ist eine Schnittansicht einer Welle für eine elektrische Maschine einer zweiten erfindungsgemäßen Ausführungsform.

The invention will now be described by way of example with reference to the drawings.

• 1 is a sectional view of a shaft for an electric machine in the first embodiment of the invention.
• 2 is a sectional view of a shaft for an electric machine of a second embodiment of the invention.

Detailed description of the invention

In the 1 and 2 become two alternative embodiments of a wave 1 . 11 shown for an electric machine. In the figures, the components of an electrical machine such as rotor, stator, electrical components and housing are not shown.

1 shows a first embodiment in which a shaft 1 an electric machine an extruded profile 2 along a section AS with at least one cooling channel K having, wherein the cooling channel K essentially a common axis to the axis of rotation of the shaft 1 forms. This is to understand that the cooling channel K essentially annular, about the axis of rotation of the shaft 1 is arranged. It is also designed in this embodiment so that it is configured continuously around the axis or has separate chambers. The extruded profile 2 has a first and a second end of the section AS on, wherein at the first end a first shaft end 3 and at the second end, a second shaft end 4 is arranged. The first wave end 3 and the second shaft end 4 are preferred by means of friction stir welding with the extruded profile 2 permanently connected. With this method, also different materials can be well connected, so as in the exemplary embodiment, an aluminum extruded profile with shaft ends made of steel.

The first cylindrical body 6 which has substantially the shape of a sleeve is formed so that an inlet Z from not shown cooling medium in the cooling channel K of the extruded profile 2 is allowed. A second cylindrical body 5 which is also substantially in the form of a sleeve is by means of a press fit P1 with the extruded profile 2 permanently connected. The second cylindrical body 5 extends in the axial direction starting from the end region of the extruded profile 2 through the first cylindrical body 6 through, the end of the second cylindrical body 5 with an excess length from the first cylindrical body 6 sticks out. The outer diameter A5 the sleeve-shaped first cylindrical body 5 is smaller than the inside diameter I6 the sleeve-shaped second cylindrical body 6 and form an annular channel A5-I6 for the feed Z of the cooling medium. In the area of the end area of the extruded profile 2 form the mutually facing end faces of the first cylindrical body 6 and the second cylindrical body 5 a gap S , so that the cooling medium from the channel A5-I6 in the cooling channel K of the extruded profile 2 can flow. The first cylindrical body 6 and the channel K of the extruded profile 2 are designed such that the cooling medium only in designated first chambers of the cooling channel K can flow. The cooling medium flows axially in the direction of the second shaft end 4 where the second shaft end 4 an embodiment on the front side R which has a deflection of the cooling medium in, separated from the first chambers, second chambers of the cooling channel K in the direction of the course A causes. To ensure the outlet are in the first shaft end 3 drilling B intended. The holes B are formed such that a fluid connection of the second chambers of the cooling channel K and a channel A6-I3 is guaranteed. The holes B extend at an angle or an inclination of gap S to the inner diameter of the first shaft end 3 , The first cylindrical body 6 is by means of a press fit P2 with the first shaft end 3 permanently connected. Alternatively, the first cylindrical body 6 be pressed in the housing, not shown. In this embodiment, the first cylindrical body 6 an air gap to the first shaft end 3 on. The first cylindrical body 6 has a gradation, whereby the inner diameter of the first shaft end 3 larger than the outer diameter of the first cylindrical body 6 , The holes B of the first shaft end 3 are therefore formed at an angle or a slope that the holes B fluidly connected with the gradation. This will be the channel A6-I3 formed, through which the cooling medium in the direction of the drain A can flow. The second cylindrical body 6 protrudes axially through the first shaft end 3 out.

A second embodiment is in 2 shown. The wave 11 includes a section AS as an extruded profile 12 is formed, wherein the extruded profile 12 at least one substantially annular cooling channel K1 formed. The cooling channel K1 may also have separate chambers which are designed so that only in chambers formed to cooling medium can flow and after a deflection of the cooling medium in the region of the second cylindrical body 4 in the other chambers, the cooling medium again from the extruded profile 12 can flow out. At both ends of the section AS of the extruded profile 12 are shaft ends 13 . 14 arranged, with the shaft ends 13 . 14 made of a different material, such as steel, than the extruded profile 12 , For example, aluminum alloy, are made. The first wave end 13 and the second shaft end 14 are with the extruded profile 12 Permanently connected by friction stir welding. Alternatively, the two shaft ends could 13 . 14 also by gluing with the section AS , get connected.

A second cylindrical body 15 is by means of a press fit P1 ' with the first shaft end 13 permanently connected. The second cylindrical body 15 extends axially through the section AS the wave 11 and a first cylindrical body 16 wherein the second cylindrical body 15 from the first cylindrical body 16 sticks out. The outer diameter of the second cylindrical body 15 and the inner diameter of the first cylindrical body 16 form a channel A15-I16 through which a cooling medium via an inlet Z can flow in the axial direction. The first cylindrical body 16 points to the extruded profile 12 an embodiment R1 such that the inner diameter of the first cylindrical body 16 Expands until it has the same outer diameter as the cooling channel K2 having. This cooling channel K2 is essentially due to the outer diameter of the second cylindrical body 15 and the inner diameter of the extruded profile 12 educated. The cooling medium can through this cooling channel K2 flow until it clears S ' reached, which by the extruded profile 12 the second end of the shaft 14 and the second cylindrical body 15 is formed. The cooling medium is over the gap S ' in the cooling channel K1 directed. The cooling medium is through the extruded profile 12 which is the cooling channel K1 training, in the direction of the first shaft end 13 directed. The first wave end 13 has an embodiment on which the cooling medium of the cooling channel K1 in the channel A16-I13 allowed, which continues to the process A leads. The embodiment is designed so that the inner diameter of the second cylindrical body 15 Expands until it has the same outer diameter as the cooling channel K1 having. channel A16-I13 is substantially annular and is defined by the outer diameter of the first cylindrical body 16 and the inner diameter of the first shaft end 13 educated. The first cylindrical body 16 is by means of a press fit P2 ' in one end of the section AS of the extruded profile 12 pressed. The first cylindrical body 16 extends in the axial direction through the first shaft end 13 and sticks out of this.

LIST OF REFERENCE NUMBERS

1, 11

wave

2, 12

Extruded

3, 13

first wave end

4, 14

second shaft end

5, 15

second cylindrical body

6, 16

first cylindrical body

AS

section

K, K1, K2

cooling channel

A6-I3

channel

A5-I6

channel

A16-I13

channel

A15-I16

channel

B

drilling

S, S '

gap

R, R1

design

A

procedure

Z

Intake

P1, P1 '

interference fit

P2, P2 '

interference fit

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• DE 102012203697 A1 [0003]

Claims (10)

Electric machine comprising a stator magnetically acting with the stator rotor, wherein the rotor is rotatably mounted about an axis of rotation, a shaft (1, 11) on which the rotor is mounted, wherein the shaft (1, 11) is designed as a hollow shaft , characterized in that the shaft (1, 11) has a section which is formed as an extruded profile (2, 12) and wherein the shaft (1, 11) has a first shaft end (3, 13) and a second shaft end (4, 14) ), wherein the first shaft end (3, 13) and the second shaft end (4, 14) with the extruded profile (2, 12) at the respective opposite ends of the extruded profile (2, 12) are permanently connected. Electric machine after Claim 1 , characterized in that the extruded profile (2, 12) is made of aluminum or aluminum alloy. Electrical machine according to at least one of the preceding claims, characterized in that the extruded profile (2, 12) has at least one cooling channel (K, K1), through which a cooling medium can flow. Electrical machine according to at least one of the preceding claims, characterized in that the first shaft end (3, 13) and the second shaft end (4, 14) are made of steel. Electrical machine according to at least one of the preceding claims, characterized in that the first shaft end (3, 13) and the second shaft end (4, 14) by means of welding, in particular by means of friction welding, with the extruded profile (2, 12) are connected. Electrical machine according to at least one of the preceding claims, characterized in that the first shaft end (3, 13) and / or the second shaft end (4, 14) and / or a first cylindrical body (6, 16) and / or a second cylindrical Body (5, 15) have a configuration (R, R1), which cause a deflection of the cooling medium. Electrical machine according to at least one of the preceding claims, characterized in that a first cylindrical body (6, 16) is arranged in the first shaft end (3, 13). Electric machine according to at least one of the preceding claims, characterized in that a second cylindrical body (5, 15) is arranged in the second shaft end (4, 14). Electric machine after Claim 7 , characterized in that the first cylindrical body (6, 16) in the first shaft end (3, 13) or the extruded profile (2, 12) is pressed. Electric machine after Claim 8 , characterized in that the second cylindrical body (5, 15) in the second shaft end (5, 15) or the extruded profile (2, 12) is pressed.

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